Breast milk in neonate oral care: oropharyngeal effects in extremely preterm infants.

Ventilator-associated pneumonia (VAP) is a frequent nosocomial infection in neonatal intensive care units (NICU). Extremely preterm infants are at highest risk of developing VAP. Several studies indicate that oral care included in a preventive protocol effectively reduces neonatal VAP incidence. We investigated the effects of oral care with breast milk on oral immune defenses and microbiota in extremely preterm infants. Thirty infants born ≤ 30 weeks gestation hospitalized at our NICU were selected and divided into three groups: oral care with breast milk, formula, or sterile water. Effects on oral immune defenses in vivo were studied using ELISA to measure lactoferrin (LF) and secretory immunoglobulin A (sIgA) in pharyngeal aspirates before and after oral care. Different LF concentrations were tested in vitro to assess their effects on loads of selected bacterial species by culture. Effects on selected bacteria potentially responsible for VAP in vivo were studied by real-time PCR detection in pharyngeal aspirates before and after oral care. Oral care with breast milk significantly increases LF concentrations to 69.8 × 103 ng/ml (p = 0.012) and sIgA to 36.8 × 103 ng/ml (p = 0.017) in vivo. These LF concentrations considerably reduce loads of E. coli, S. epidermidis, S. aureus, and P. aeruginosa, in vitro. However, contrary to our expectation, no effect on colonization of bacteria most commonly responsible for VAP was found in vivo. CONCLUSION: In extremely preterm infants, oral care with breast milk increases local immune defense markers (LF, sIgA), which combat bacterial infections. Further clinical trials should be conducted to evaluate their effects on VAP prevention in neonates. WHAT IS KNOWN: • The population at higher risk to develop VAP are preterm infants. • Several studies indicate oral care within a preventive bundle is effective in reducing neonatal VAP incidence. WHAT IS NEW: • In extremely premature infants, oral care with breast milk causes a significant increase in local immune defences in terms of lactoferrin (LF) and secretory immunoglobulin A (sIgA). • LF concentrations obtained after oral care with breast milk decreased loads of bacteria most commonly responsible for VAP in premature infants under experimental in-vitro.

Quality risk management of the chimeric antigen receptor T cell pharmaceutical circuit in one of the first qualified European centers.

BACKGROUND AIMS: According to European Directive 2001/83/EC, chimeric antigen receptor T (CAR T) cells belong to a new class of medicines referred to as advanced therapy medicinal products (ATMPs). The specific features and complexity of these products require a total reorganization of the hospital circuit, from cell collection from the patient to administration of the final medicinal product. In France, at the cell stage, products are under the responsibility of a cell therapy unit (CTU) that controls, manipulates (if necessary) and ships cells to the manufacturing site. However, the final product is a medicinal product, and as with any other medicine, ATMPs have to be received, stored and further reconstituted for final distribution under the responsibility of the hospital pharmacy. The aim of our work was to perform a risk analysis of this circuit according to International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use Q9 guidelines on quality risk management. METHODS: We evaluated the activities carried out by the Saint-Louis Hospital CTU and pharmacy. Process mapping was established to trace all the steps of the circuit and to identify potential risks or failures. The risk analysis was performed according to failure mode, effects and criticality analysis. The criticality of each risk (minor [Mi], moderate [Mo], significant [S] or major [Ma]) was scored, and corrective actions or preventive actions (CAPAs) for Mo, S and Ma risks were proposed. RESULTS: We identified five Mo, six S and no Ma risks for the CTU part of the process. The most frequent risk was traceability failure. To reduce its frequency, we developed and validated software dedicated to ATMP activities. Another S risk was non-compliance of CAR T cell-specific steps due to the significant variability between companies. Our CAPA process was to implement procedures and design information sheets specific to each CAR T-cell program. In addition, critical steps were added to the ATMP software. Our CAPA process allowed us to reduce the criticality of identified risks to one Mi, seven Mo and three S. For the pharmacy part of the process, five Mo, two S and one Ma risk were identified. The most critical risk was compromised integrity of the CAR T-cell bag at the time of thawing. In case of unavailability of a backup bag, we designed and validated a degraded mode of operation allowing product recovery. In this exceptional circumstance, an agreement has to be signed between the physician, pharmacy, CTU and sponsor or marketing authorization holder. The implemented CAPA process allowed us to reduce the criticality of risks to three Mi and five Mo. CONCLUSIONS: Our risk analysis identified several Mo and S risks but only one Ma risk. The implementation of the CAPA process allowed for controlling some risks by decreasing their frequency and/or criticality or by increasing their detectability. The close collaboration between the CTU and pharmacy allows complete traceability of the CAR T-cell circuit, which is essential to guarantee safe use.